Digital power amplifier with RF sampling rate and wide tuning range

ABSTRACT

A switching power amplifier includes logic circuitry that generates first and second components of a differential signal, based on received amplitude code and a delayed version of the same. The amplitude code includes a sign and a magnitude. When the sign is positive, a first logic path is configured to generate the first component based on the received amplitude code and the second logic path is configured to generate the second component based on the delayed amplitude code. When the sign is negative, the first logic path is configured to generate the first component based on the delayed amplitude code and the second logic path is configured to generate the second component based on the received amplitude code. The switching power amplifier further includes a differential-to-single ended conversion circuit configured to generate a single-ended signal based on the differential signal.

BACKGROUND Technical Field

This disclosure is directed to amplifier circuits, and moreparticularly, power amplifiers for wireless communications circuits.

Description of the Related Art

Digital power amplifiers, also known as switching power amplifiers, arecommonly used in wireless communications systems. Relative to linearpower amplifiers, switching power amplifiers offer better efficiency atback-off power (e.g., reduction of output power relative to a reductionof input power), since switching power amplifiers operate at theirsaturated power. In contrast, the efficiency of a linear power amplifiermay be degraded at higher back-off power. Certain types of transmitters,such as ultra-wideband (UWB) transmitters, have a high peak-to-averagepower ratio, and thus may operate at higher back-off power. Thus,switching power amplifiers are commonly used in UWB transmitters.

SUMMARY

A switching power amplifier is disclosed. In one embodiment, a switchingpower amplifier includes logic circuitry that generates first and secondcomponents of a differential signal, based on received amplitude codeand a delayed version of the same. The amplitude code includes a signand a magnitude. When the sign is positive, a first logic path isconfigured to generate the first component based on the receivedamplitude code and the second logic path is configured to generate thesecond component based on the delayed amplitude code. When the sign isnegative, the first logic path is configured to generate the firstcomponent based on the delayed amplitude code and the second logic pathis configured to generate the second component based on the receivedamplitude code. The switching power amplifier further includes adifferential-to-single ended conversion circuit configured to generate asingle-ended signal based on the differential signal.

In various embodiments, the differential-to-single ended conversioncircuit includes an inductive-capacitive (LC) tuning circuit including afirst coil divided into a first sub-coil and a second sub-coil, whereinthe LC tuning circuit further includes a first capacitor coupled inseries between the first sub-coil and the second sub-coil. The firstcapacitor is, in one embodiment, a variable capacitor, and can be aswitched capacitor.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description makes reference to the accompanyingdrawings, which are now briefly described.

FIG. 1 is a block diagram of one embodiment of a switching amplifier.

FIG. 2 is a diagram of one embodiment of an input circuit of a switchingamplifier.

FIG. 3 is a timing diagram illustrating operation of one embodiment ofan input circuit of a switching amplifier.

FIG. 4 is a schematic diagram of one embodiment of adifferential-to-single ended converter circuit of a switching amplifier.

FIG. 5 is a block diagram of one embodiment of a transmitter.

FIG. 6 is a flow diagram illustrating one embodiment of a method foroperating a switching amplifier.

FIG. 7 a block diagram of one embodiment of a computer system.

Although the embodiments disclosed herein are susceptible to variousmodifications and alternative forms, specific embodiments are shown byway of example in the drawings and are described herein in detail. Itshould be understood, however, that drawings and detailed descriptionthereto are not intended to limit the scope of the claims to theparticular forms disclosed. On the contrary, this application isintended to cover all modifications, equivalents and alternativesfalling within the spirit and scope of the disclosure of the presentapplication as defined by the appended claims.

This disclosure includes references to “one embodiment,” “a particularembodiment,” “some embodiments,” “various embodiments,” or “anembodiment.” The appearances of the phrases “in one embodiment,” “in aparticular embodiment,” “in some embodiments,” “in various embodiments,”or “in an embodiment” do not necessarily refer to the same embodiment.Particular features, structures, or characteristics may be combined inany suitable manner consistent with this disclosure.

Within this disclosure, different entities (which may variously bereferred to as “units,” “circuits,” other components, etc.) may bedescribed or claimed as “configured” to perform one or more tasks oroperations. This formulation [entity] configured to [perform one or moretasks] is used herein to refer to structure (i.e., something physical,such as an electronic circuit). More specifically, this formulation isused to indicate that this structure is arranged to perform the one ormore tasks during operation. A structure can be said to be “configuredto” perform some task even if the structure is not currently beingoperated. A “credit distribution circuit configured to distributecredits to a plurality of processor cores” is intended to cover, forexample, an integrated circuit that has circuitry that performs thisfunction during operation, even if the integrated circuit in question isnot currently being used (e.g., a power supply is not connected to it).Thus, an entity described or recited as “configured to” perform sometask refers to something physical, such as a device, circuit, memorystoring program instructions executable to implement the task, etc. Thisphrase is not used herein to refer to something intangible.

The term “configured to” is not intended to mean “configurable to.” Anunprogrammed FPGA, for example, would not be considered to be“configured to” perform some specific function, although it may be“configurable to” perform that function after programming.

Reciting in the appended claims that a structure is “configured to”perform one or more tasks is expressly intended not to invoke 35 U.S.C.§ 112(f) for that claim element. Accordingly, none of the claims in thisapplication as filed are intended to be interpreted as havingmeans-plus-function elements. Should Applicant wish to invoke Section112(f) during prosecution, it will recite claim elements using the“means for” [performing a function] construct.

As used herein, the term “based on” is used to describe one or morefactors that affect a determination. This term does not foreclose thepossibility that additional factors may affect the determination. Thatis, a determination may be solely based on specified factors or based onthe specified factors as well as other, unspecified factors. Considerthe phrase “determine A based on B.” This phrase specifies that B is afactor that is used to determine A or that affects the determination ofA. This phrase does not foreclose that the determination of A may alsobe based on some other factor, such as C. This phrase is also intendedto cover an embodiment in which A is determined based solely on B. Asused herein, the phrase “based on” is synonymous with the phrase “basedat least in part on.”

As used herein, the phrase “in response to” describes one or morefactors that trigger an effect. This phrase does not foreclose thepossibility that additional factors may affect or otherwise trigger theeffect. That is, an effect may be solely in response to those factors,or may be in response to the specified factors as well as other,unspecified factors. Consider the phrase “perform A in response to B.”This phrase specifies that B is a factor that triggers the performanceof A. This phrase does not foreclose that performing A may also be inresponse to some other factor, such as C. This phrase is also intendedto cover an embodiment in which A is performed solely in response to B.

As used herein, the terms “first,” “second,” etc. are used as labels fornouns that they precede, and do not imply any type of ordering (e.g.,spatial, temporal, logical, etc.), unless stated otherwise. For example,in a register file having eight registers, the terms “first register”and “second register” can be used to refer to any two of the eightregisters, and not, for example, just logical registers 0 and 1.

When used in the claims, the term “or” is used as an inclusive or andnot as an exclusive or. For example, the phrase “at least one of x, y,or z” means any one of x, y, and z, as well as any combination thereof.

In the following description, numerous specific details are set forth toprovide a thorough understanding of the disclosed embodiments. Onehaving ordinary skill in the art, however, should recognize that aspectsof disclosed embodiments might be practiced without these specificdetails. In some instances, well-known circuits, structures, signals,computer program instruction, and techniques have not been shown indetail to avoid obscuring the disclosed embodiments.

DETAILED DESCRIPTION OF EMBODIMENTS

The present disclosure is directed to digital power amplifier, orswitching power amplifier. Most conventional Class-D PAs amplify adifferential input signal through switching buffers and a series-LCnetwork. Buffers provide a square-wave voltage which is then filtered bythe series-LC network in current domain and converted through a balun toa single-ended signal at the output. Signal power can then be adjustedby adjusting the number of buffers that are actively switching comparedto the number of buffers that are static, e.g., fully switched to eitherlow or high state. For each buffer, a pre-driver with an enable signal(EN) can be used to adjust the number of drivers. Meanwhile, theseries-LC network is tuned for desired transmit power and optimumefficiency.

Ultra-wideband (UWB) signals provide an opportunity to simplify thepower amplifier design by using only a single core to generate the realsignal that is needed to generate the required pulses at RF. To cover“negative magnitudes” of either pulse shape or the data, a simpleinversion of the radio frequency (RF) clock signal may be sufficient.

Switching power amplifiers, in various embodiments, have two inputs: (1)the amplitude code and (2) the carrier (e.g., the clock signal at RF).Depending on the specific implementation, amplitude code may beconsidered as a signed-number or the sign can be treated as phasemodulation to the carrier. In various embodiments of a switchingamplifier according to this disclosure, a sign-magnitude amplitude codeand a constant-phase carrier is used. The amplitude signal (or amplitudecode) and the carrier are multiplied to generate first and secondcomponents of a differential signal used to drive the switching poweramplifier units to generate the required pulses at RF frequency. Thishowever presents a challenge in designing the operation of combining theclock signal and the amplitude code at RF without timing violationsacross process, voltage, and temperature variations. In particular,meeting both hold time and set up time requirements for thesynchronization of the amplitude code and RF clock signal can bechallenging. Using automated timing analysis tools cause overdesignwhich can be costly at RF. Accordingly, the switching power amplifierdisclosed herein relaxes the timing requirements to meet setup and holdtime requirements while still being able to combine the amplitude codeand clock signal at RF.

The timing requirements may be relaxed by producing a replica of theamplitude code that is delayed by one-half cycle of a clock signal at RFfrequency. Both components of the RF clock signal may be driven byeither phase of the RF clock signal. The originally received version ofthe amplitude code may be evaluated on a first phase of the RF clocksignal (e.g., when the RF clock signal is high) while the delay versionmay be evaluated based on a second phase of the RF clock signal (e.g.,when the RF clock signal is low). This allows resulting enable signals ahalf-period of settling time.

Switching power amplifiers used in UWB transmitters typically have awide tuning range requirement. Achieving a wide tuning range with afixed LC tank is not preferred for output power and efficiency reasons.Some switching power amplifiers use series LC tuning at the output ofthe power amplifier. However this configuration can be difficult totune. For example, tuning the series capacitor (e.g., coupled between adifferential signal output and an inductor coil) degrades linearity,output power and efficiency since the series capacitor experiences thefull signal swing. Alternative embodiments rely on switching theinductance, but this is also difficult and can degrade output power andefficiency. Another alternative embodiment involves placing a parallelcapacitor on the input side of the balun (or inductor coil) to tune thetank circuit, but this can reduce the maximum power achievable due tocapacitive division, particularly when a wide tuning range is needed.

The present disclosure contemplates a power amplifier in which thecenter-tap connection of the primary coil is broken and adding, inseries, a variable capacitor (e.g., as a switched capacitor) in thesignal path. Due to differential signaling, the switches inside thevariable/switched capacitor array does not experience any signal swingin the on mode, if designed properly with low on-resistance. Theoriginal series capacitance may be increased such that the net seriescapacitance is at the desired value. When the variable capacitor isimplemented as a switched capacitor, the reliability and linearityimpact of the OFF mode switched-capacitors units can be addressed byproper biasing of the drain/source terminals in that mode.

Various embodiments of a switching amplifier implementing the solutionsdiscussed above are now discussed in further detail.

FIG. 1 is a block diagram of one embodiment of a switching poweramplifier (alternatively referred to as a digital power amplifier). Inthe embodiment shown, switching power amplifier 100 includes an inputcircuit 101 and a differential-to-single ended conversion (DSE) circuit107. Input circuit 101 includes a delay circuit 102 as well as logiccircuits 104 and 105. The output of these two logic circuits comprise adifferential signal having a first component, Dp, and a secondcomponent, Dn, provided to DSE circuit 107. The output of DSE circuit107, out, may be an amplitude modulated signal suitable for wirelesstransmission.

Delay circuit 101 in the embodiment shown receives amplitude code(‘Amp’), e.g., a digital filter. The amplitude code is a multi-bitdigital signal including a number of bits indicative of a magnitude anda sign bit indicating whether the value is positive or negative. Delaycircuit 101 also receives a clock signal, ClkRf, the frequency of whichcorresponds to a carrier signal of, e.g., a transmitter in whichswitching power amplifier 100 is implemented. Using the first copy ofthe amplitude code, ‘Amp’, delay circuit 102 generates a second copy ofthe amplitude code, ‘AmpD’. In the embodiment shown, AmpD has a valueequivalent to Amp, but is delayed by one half cycle of ClkRf. Both Ampand AmpD are provided to logic circuits 104 and 105, along with theclock signal, ClkRf.

Logic circuit 104 in the embodiment shown generates a first component ofthe differential signal, Dp. Meanwhile, logic circuit 105 generates asecond component of the differential signal, Dp. Generation of thesesignals is based at least in part on whether the sign contained in theamplitude code is positive or negative. When the sign is positive, thelogic circuit 104 generates the first component, Dp, based on thereceived amplitude code, Amp, while logic circuit 105 generates thesecond component, Dn, based on the delayed amplitude code, AmpD. Whenthe sign is negative, the logic circuit 104 generates Dp based on thedelayed amplitude code, AmpD, while logic circuit 105 generates Dn basedon the received amplitude code, Amp. When the sign is positive, Dp isdriven by the clock signal, ClkRf, while Dn is driven by the oppositephase of ClkRf (referred to below as ClkRf_). When the sign is negative,Dp is driven by ClkRf_, while Dn is driven by ClkRf.

The differential signal components Dp and Dn are provided from inputcircuit 101 to DSE circuit 107. Taken collectively, Dp and Dn form anamplitude modulated differential signal having a carrier frequencyequivalent to ClkRf. DSE circuit 107 converts the differential signalinto a single-ended signal, ‘Out’, which is suitable for wirelesstransmission from an antenna.

FIG. 2 is a diagram of one embodiment of an input circuit of a switchingamplifier. In the embodiment shown, input circuit 101 includes a delaycircuit 102, logic circuit 104, and logic circuit 105. Input circuit 101in this particular embodiment also includes a local oscillator 205,although this component may be implemented separately from the othershown here. The delay circuit includes a number of flip-flops 203. Logiccircuits 104 and 105 each include a number of AND gates and OR gates.

Amplitude code, Amp[n:0], is received in a group of magnitude bits,Amp[n−1:0], and a sign bit, Amp[n]. These bits are provided tocorrespondingly coupled ones of flip-flops 203. It is noted that only asingle flip-flop 203 is shown as receiving Amp[n−1:0], the symbol shownin the drawing may in fact be representative of multiple flip-flops, onefor each bit of the magnitude component of the amplitude code.

The output of the first set of flip-flops 203 (left-hand side),EnP[n−1:0] and SignP, are equivalent to the amplitude code as input.When ClkRf is low, its complement, ClkRf_ is high, and thus theseflip-flops are transparent to the incoming amplitude code. When ClkRfgoes high (and thus, ClkRf_ goes low), the amplitude code is captured.When ClkRf is high, the captured amplitude code, as EnP[n−1:0] andSignP, is captured into the second set of flip-flops 203 (right handside). One half-clock cycle later, when ClkRf falls low again, thesecond set of flip-flops 203 outputs EnN[n−1:0] and SignN, which iseffectively a delayed version of the previously received amplitude code.

Logic circuits 104 and 105 are identically arranged logic circuits inthe embodiment shown, including a number of AND gates and a number of ORgates. It is noted that the AND gates receiving EnP[n−1:0] andEnN[n−1:0] may represent a number of AND gates, one for each bit of themagnitude portion of the amplitude value. Similarly, the number of ORgates providing the output signals Dp and Dn may match the number ofbits. The outputs of the OR gates may be coupled together to generatethe respective magnitudes of Dp and Dn.

Only one of the SignP or SignN bits is a logic high at a given time.When SignP is high (indicating a positive value), SignN_ is also high(while SignN is low). Similarly, when SignN is high (indicating anegative value), SignP is low while SignP_ is positive. These logicstates affect which amplitude values are used to generate the Dp and Dncomponents of the differential signal.

When SignP is positive, logic circuit 104 generates Dp based on thereceived amplitude code (provided as EnP[n−1:0]), while logic circuit105 generates Dn based on the delayed amplitude code (provided asEnN[n−1:0]). Furthermore, when the sign is positive, logic circuit 104generates Dp in accordance with ClkRf, one half clock cycle before logiccircuit 105 generates Dn.

When the sign is negative, Dp is generated by logic circuit based on thedelayed amplitude code, and in accordance with ClkRf_, which is oppositein phase with respect to ClkRf. Accordingly, Dp is generated one halfclock cycle later than Dn when the sign is negative. Logic circuit 105,when the sign is negative, generates Dn based on the received amplitudecode, as SignP_ is also positive in this case. Furthermore, Dn, as notedabove, is generated according to ClkRf instead of ClkRf_, and is thusgenerated one half clock cycle prior to the generation of Dp. Generallyspeaking, the received copy of the amplitude code is driven by thepositive phase of ClkRf, while the delayed copy is driven by ClkRf_.

FIG. 3 is a timing diagram illustrating operation of one embodiment ofan input circuit of a switching amplifier. In the illustrated example,the clock signal ClkRf is shown, although it is to be understood thatits complement, ClkRf_ is used as well. When ClkRf is high, ClkRf_ islow, and vice versa.

‘Amp’ in the embodiment shown represents the received amplitude code,while ‘AmpD’ represents the delayed amplitude code. In Cycle 1 of theexample, an amplitude code representing a value of +3 is received. Sincethe sign is positive in this cycle, Dp is generated prior to Dn, and isgenerated by the received amplitude code, while Dn is generated based onthe delayed amplitude code. Furthermore, since the sign is positive, Dpis generated one half cycle prior to the generation of Dn, as shown inthe timing diagram. The magnitude of both the Dp and Dn outputs is 3×for this cycle.

In Cycle 2, the received amplitude code represents a value of +1. Sincethe sign is positive, Dp is driven by ClkRf, while Dn is driven byClkRf_. Thus, Dp is generated prior to Dn, by one half clock cycle. Dpis generated based on Amp, while Dn is generated based on AmpD.

In Cycle 3, the amplitude code is received representing a value of −2.Since the sign is negative in this case, Dn is generated prior to Dp.The received amplitude code, Amp, driven by ClkRf, is used to generateDn when the sign is negative. Thereafter, the delayed amplitude code,AmpD, driven by ClkRf_, is used to generate Dp, one half clock cycleafter the generation of Dn.

In Cycle 4, the received amplitude code represents a value of +1, andthus Dp is generated based on Amp, driven by ClkRf, while Dn isgenerated based on AmpD, driven by ClkRf_.

FIG. 4 is a schematic diagram of one embodiment of adifferential-to-single ended converter circuit of a switching amplifier.In the embodiment shown, DSE circuit 107 includes a primary side and asecondary side. The primary side includes inductor L1, which is dividedinto sub-coils L1A and L1B, capacitors C1, C2, and C3. Capacitor C2 iscoupled in series between the Dp terminal and L1A. Capacitor C3 iscoupled between the Dn terminal and L1B. The secondary side includesinductor L2, shown here as divided into sub-coils L2A and L2B.

In the embodiment shown, the center tap of the primary coil L1 is brokento add a series capacitor C1. C1 is thus in coupled in series betweenL1A and L2A. As shown here, C1 is a variable capacitor, and in oneembodiment, may be a switched capacitor. Due to differential signaling,when implemented as a switched capacitor, the switches of C1 inside theswitched capacitor array (implemented using capacitor-coupledtransistors) experiences no signal swing in ON mode, with proper lowon-resistance. The original series capacitance (e.g., C2 and C3) may beincreased in this case to ensure that the net series capacitance is atthe desired value. With respect to the reliability and linearity impactof the off-mode switched capacitor, proper biasing of the source anddrain terminals can be used to address this issue. The technique ofplacing a variable/switched capacitor in series with the inductor coilsas shown in FIG. 4 may allow the amplifier to have a wide frequencyrange without degrading critical performance parameters, such aslinearity, output power, and efficiency.

As shown in FIG. 4, the signal received on the primary side is adifferential signal having components Dp and Dn. Energy from thedifferential signal is transferred through mutual inductance to coilsL2A and L2B. Since L2B is coupled to ground at one terminal, the outputsignal, ‘Out’, is a single ended signal. Based on the operationdescribed above in the input circuit, this signal is an amplitudemodulated signal having a carrier frequency at RF, which corresponds tothe clock signal frequency. Accordingly, the various embodiments of theswitching amplifier disclose herein effectively performs directamplitude modulation at a desired carrier frequency.

FIG. 5 is a block diagram of one embodiment of a transmitter circuithaving a filter and a power amplifier. In the embodiment shown,transmitter circuit 500 includes a filter 502 and a switching poweramplifier 100. Filter 502 may be a digital filter that generates andprovides its output data as amplitude code to switching power amplifier100. Furthermore, in some embodiments, filter 502 may provide amplitudecode to switching power amplifiers 100 at a data rate corresponding tothe radio frequency of the transmitter system (e.g., ClkRf in thevarious circuits discussed above).

Switching power amplifier 100 in the embodiment shown may be a one of anembodiment falling within the scope of those discussed above. Switchingmay occur at the rate of the RF signal, which corresponds to the clocksignal, ClkRf, as previously discussed. When receiving the modulationcode at switching the carrier frequency, switching power amplifier 100performs direct amplitude modulation at the RF. Accordingly, the outputsignal is an amplitude modulated signal based on the modulation codeprovided to switching power amplifier 100. The output signal, anamplitude modulated RF signal, may then be provided to antenna 506 forwireless transmission.

FIG. 6 is a flow diagram of one embodiment of a method for operating aswitching power amplifier. Method 600 as discussed herein may beperformed with any of the switching power amplifier embodimentsdiscussed above and variations thereof. Embodiments of a switchingamplifier not explicitly discussed herein are also contemplated as beingable to carry out method 600, and may thus fall within the scope of thisdisclosure.

Method 600 begins with receiving a first amplitude code to a switchingpower amplifier circuit, the amplitude code including one or more bitsindicative of a magnitude and a bit indicative of a sign (block 605).The method further includes generating, using a delay circuit, a secondamplitude code, wherein the second amplitude code is a delayed versionof the first amplitude code (block 610). A differential output signal isgenerated based on the first amplitude code and the second amplitudecode. When the sign is positive, a first logic circuit generates a firstcomponent of the differential output signal based on the first amplitudecode, while a second logic circuit generates a second component of thedifferential signal based on the second amplitude code (block 615). Whenthe sign is negative, the first logic circuit generates the firstcomponent of the differential output signal based on the secondamplitude code and the second logic circuit generates the secondcomponent of the differential signal based on the first amplitude code(block 620). In various embodiments, the differential signal is anamplitude modulated signal.

In various embodiments, the method includes providing, from a localoscillator, a clock signal to the delay circuit, wherein generating thesecond amplitude code comprises providing a delay of one half cycle ofthe clock signal to the delay. The frequency of the clock signal is aradio frequency (RF) of a transmitter circuit.

Embodiments are further contemplated wherein the method includesconverting the differential signal to a single-ended signal using adifferential-to-single ended conversion circuit, thedifferential-to-single ended conversion circuit comprising an LC tankcircuit. Such embodiments may also includes setting a capacitance of theLC tank circuit by varying a capacitance of a capacitor coupled inseries between a first sub-coil and a second sub-coil of the LC tankcircuit.

FIG. 7 is a block diagram of one embodiment an example computer system.Computer system 700 in the embodiment shown includes a processor circuit705, analog/mixed signal circuitry 706, memory circuit 707, andinput/output circuitry 709. Input/output circuitry 709 includes anembodiment of amplifier 100 which falls within the scope of any of thevarious embodiments of the same discussed above.

Processor circuit 705 may be one of a number of different types ofprocessors, e.g., a heterogeneous multi-core processor. In variousembodiments, processor cores in processor circuit 705 may include coresoptimized for performance, power consumption, or particular types ofprocessing functions.

Memory circuit 707 may be one or more of a number of different types ofmemory, including random access memory (dynamic and/or static), graphicsmemory, flash memory, disk storage, and so on. Generally speaking,memory circuit 707 may implement any type of memory technology thatallows for persistent storage of information.

Analog/mixed signal circuitry 706 may include a number of differenttypes of circuits that include at least some analog functionality. Suchcircuits may include power supply circuits, such as voltage regulatorsused to provide supply voltages to other circuits within computer system700. Metrology circuitry used to measure various circuit/performanceparameters may also be included. Power management circuits may also beincluded in analog/mixed signal circuitry, and may implement functionsto control power consumption and temperature in various parts ofcomputer system 700.

Input/output circuitry 709 includes various circuits for conveyinginformation to destinations external to computer system 700, as well asfor receiving information from external sources. This may includecircuitry for outputting information to a display, audio information,and so on. Input/output circuitry 709 may also include wirelesscommunications circuitry, some of which may implement an embodiment ofamplifier 100 as discussed herein.

Numerous variations and modifications will become apparent to thoseskilled in the art once the above disclosure is fully appreciated. It isintended that the following claims be interpreted to embrace all suchvariations and modifications.

What is claimed is:
 1. An apparatus comprising: a switching poweramplifier input circuit including: logic circuitry having first andsecond logic paths configured to generate first and second components ofa differential signal, respectively, based on a received amplitude codeand a delayed amplitude code, wherein the amplitude code includes a signand a magnitude; wherein, when the sign is positive, the first logicpath is configured to generate the first component based on the receivedamplitude code and the second logic path is configured to generate thesecond component based on the delayed amplitude code; wherein, when thesign is negative, the first logic path is configured to generate thefirst component based on the delayed amplitude code and the second logicpath is configured to generate the second component based on thereceived amplitude code; and a differential-to-single ended conversioncircuit configured to generate a single-ended signal based on thedifferential signal.
 2. The apparatus of claim 1, further comprising adelay circuit configured to apply a delay to the received amplitude codeto generate the delayed amplitude code.
 3. The apparatus of claim 2,further comprising a local oscillator circuit configured to provide aclock signal and a complement of the clock signal to the delay circuitand the logic circuitry, wherein a frequency of the clock signal is aradio frequency (RF) of a transmitter circuit.
 4. The apparatus of claim3, wherein the delay circuit is configured to generate the delayedamplitude code by providing a delay equivalent to one half cycle of theclock signal.
 5. The apparatus of claim 2, wherein the delay circuitcomprises a first plurality of flip-flop circuits configured to apply adelay to one or more bits indicative of the magnitude of the receivedamplitude code, and a second plurality of flip-flops configured to applya delay to a bit indicative of the sign of the received amplitude code.6. The apparatus of claim 1, wherein the differential-to-single endedconversion circuit includes an inductive-capacitive (LC) tuning circuitincluding a first coil, and further includes a second coil, wherein afirst coil is configured to electromagnetically convey the differentialsignal to the second coil.
 7. The apparatus of claim 6, wherein thefirst coil includes a first sub-coil and a second sub-coil, and whereinthe LC tuning circuit further includes a first capacitor coupled inseries between the first sub-coil and the second sub-coil.
 8. Theapparatus of claim 7, wherein the first capacitor is a variablecapacitor.
 9. A method comprising: receiving a first amplitude code to aswitching power amplifier circuit, the amplitude code including one ormore bits indicative of a magnitude and a bit indicative of a sign;generating, using a delay circuit, a second amplitude code, wherein thesecond amplitude code is a delayed version of the first amplitude code;generating a differential output signal based on the first amplitudecode and the second amplitude code, wherein generating the differentialoutput signal comprises: when the sign is positive, generating, in afirst logic circuit, a first component of the differential output signalbased on the first amplitude code and generating, in a second logiccircuit, a second component of the differential output signal based onthe second amplitude code; and when the sign is negative, generating, inthe first logic circuit, the first component of the differential outputsignal based on the second amplitude code and generating, in the secondlogic circuit, the second component of the differential signal based onthe first amplitude code.
 10. The method of claim 9, further comprising:providing, from a local oscillator, a clock signal to the delay circuit,wherein generating the second amplitude code comprises providing a delayof one half cycle of the clock signal to the delay.
 11. The method ofclaim 10, wherein a frequency of the clock signal is a radio frequency(RF) of a transmitter circuit.
 12. The method of claim 9, furthercomprising converting the differential output signal to a single-endedsignal using a differential-to-single ended conversion circuit, thedifferential-to-single ended conversion circuit comprising an LC tankcircuit.
 13. The method of claim 12, further comprising setting acapacitance of the LC tank circuit by varying a capacitance of acapacitor coupled in series between a first sub-coil and a secondsub-coil of the LC tank circuit.
 14. The method of claim 9, wherein thedifferential output signal is an amplitude modulated signal.